fash0 / detectron2 /engine /train_loop.py
IDM-VTON
update IDM-VTON Demo
938e515
# -*- coding: utf-8 -*-
# Copyright (c) Facebook, Inc. and its affiliates.
import concurrent.futures
import logging
import numpy as np
import time
import weakref
from typing import List, Mapping, Optional
import torch
from torch.nn.parallel import DataParallel, DistributedDataParallel
import detectron2.utils.comm as comm
from detectron2.utils.events import EventStorage, get_event_storage
from detectron2.utils.logger import _log_api_usage
__all__ = ["HookBase", "TrainerBase", "SimpleTrainer", "AMPTrainer"]
class HookBase:
"""
Base class for hooks that can be registered with :class:`TrainerBase`.
Each hook can implement 4 methods. The way they are called is demonstrated
in the following snippet:
::
hook.before_train()
for iter in range(start_iter, max_iter):
hook.before_step()
trainer.run_step()
hook.after_step()
iter += 1
hook.after_train()
Notes:
1. In the hook method, users can access ``self.trainer`` to access more
properties about the context (e.g., model, current iteration, or config
if using :class:`DefaultTrainer`).
2. A hook that does something in :meth:`before_step` can often be
implemented equivalently in :meth:`after_step`.
If the hook takes non-trivial time, it is strongly recommended to
implement the hook in :meth:`after_step` instead of :meth:`before_step`.
The convention is that :meth:`before_step` should only take negligible time.
Following this convention will allow hooks that do care about the difference
between :meth:`before_step` and :meth:`after_step` (e.g., timer) to
function properly.
"""
trainer: "TrainerBase" = None
"""
A weak reference to the trainer object. Set by the trainer when the hook is registered.
"""
def before_train(self):
"""
Called before the first iteration.
"""
pass
def after_train(self):
"""
Called after the last iteration.
"""
pass
def before_step(self):
"""
Called before each iteration.
"""
pass
def after_backward(self):
"""
Called after the backward pass of each iteration.
"""
pass
def after_step(self):
"""
Called after each iteration.
"""
pass
def state_dict(self):
"""
Hooks are stateless by default, but can be made checkpointable by
implementing `state_dict` and `load_state_dict`.
"""
return {}
class TrainerBase:
"""
Base class for iterative trainer with hooks.
The only assumption we made here is: the training runs in a loop.
A subclass can implement what the loop is.
We made no assumptions about the existence of dataloader, optimizer, model, etc.
Attributes:
iter(int): the current iteration.
start_iter(int): The iteration to start with.
By convention the minimum possible value is 0.
max_iter(int): The iteration to end training.
storage(EventStorage): An EventStorage that's opened during the course of training.
"""
def __init__(self) -> None:
self._hooks: List[HookBase] = []
self.iter: int = 0
self.start_iter: int = 0
self.max_iter: int
self.storage: EventStorage
_log_api_usage("trainer." + self.__class__.__name__)
def register_hooks(self, hooks: List[Optional[HookBase]]) -> None:
"""
Register hooks to the trainer. The hooks are executed in the order
they are registered.
Args:
hooks (list[Optional[HookBase]]): list of hooks
"""
hooks = [h for h in hooks if h is not None]
for h in hooks:
assert isinstance(h, HookBase)
# To avoid circular reference, hooks and trainer cannot own each other.
# This normally does not matter, but will cause memory leak if the
# involved objects contain __del__:
# See http://engineering.hearsaysocial.com/2013/06/16/circular-references-in-python/
h.trainer = weakref.proxy(self)
self._hooks.extend(hooks)
def train(self, start_iter: int, max_iter: int):
"""
Args:
start_iter, max_iter (int): See docs above
"""
logger = logging.getLogger(__name__)
logger.info("Starting training from iteration {}".format(start_iter))
self.iter = self.start_iter = start_iter
self.max_iter = max_iter
with EventStorage(start_iter) as self.storage:
try:
self.before_train()
for self.iter in range(start_iter, max_iter):
self.before_step()
self.run_step()
self.after_step()
# self.iter == max_iter can be used by `after_train` to
# tell whether the training successfully finished or failed
# due to exceptions.
self.iter += 1
except Exception:
logger.exception("Exception during training:")
raise
finally:
self.after_train()
def before_train(self):
for h in self._hooks:
h.before_train()
def after_train(self):
self.storage.iter = self.iter
for h in self._hooks:
h.after_train()
def before_step(self):
# Maintain the invariant that storage.iter == trainer.iter
# for the entire execution of each step
self.storage.iter = self.iter
for h in self._hooks:
h.before_step()
def after_backward(self):
for h in self._hooks:
h.after_backward()
def after_step(self):
for h in self._hooks:
h.after_step()
def run_step(self):
raise NotImplementedError
def state_dict(self):
ret = {"iteration": self.iter}
hooks_state = {}
for h in self._hooks:
sd = h.state_dict()
if sd:
name = type(h).__qualname__
if name in hooks_state:
# TODO handle repetitive stateful hooks
continue
hooks_state[name] = sd
if hooks_state:
ret["hooks"] = hooks_state
return ret
def load_state_dict(self, state_dict):
logger = logging.getLogger(__name__)
self.iter = state_dict["iteration"]
for key, value in state_dict.get("hooks", {}).items():
for h in self._hooks:
try:
name = type(h).__qualname__
except AttributeError:
continue
if name == key:
h.load_state_dict(value)
break
else:
logger.warning(f"Cannot find the hook '{key}', its state_dict is ignored.")
class SimpleTrainer(TrainerBase):
"""
A simple trainer for the most common type of task:
single-cost single-optimizer single-data-source iterative optimization,
optionally using data-parallelism.
It assumes that every step, you:
1. Compute the loss with a data from the data_loader.
2. Compute the gradients with the above loss.
3. Update the model with the optimizer.
All other tasks during training (checkpointing, logging, evaluation, LR schedule)
are maintained by hooks, which can be registered by :meth:`TrainerBase.register_hooks`.
If you want to do anything fancier than this,
either subclass TrainerBase and implement your own `run_step`,
or write your own training loop.
"""
def __init__(
self,
model,
data_loader,
optimizer,
gather_metric_period=1,
zero_grad_before_forward=False,
async_write_metrics=False,
):
"""
Args:
model: a torch Module. Takes a data from data_loader and returns a
dict of losses.
data_loader: an iterable. Contains data to be used to call model.
optimizer: a torch optimizer.
gather_metric_period: an int. Every gather_metric_period iterations
the metrics are gathered from all the ranks to rank 0 and logged.
zero_grad_before_forward: whether to zero the gradients before the forward.
async_write_metrics: bool. If True, then write metrics asynchronously to improve
training speed
"""
super().__init__()
"""
We set the model to training mode in the trainer.
However it's valid to train a model that's in eval mode.
If you want your model (or a submodule of it) to behave
like evaluation during training, you can overwrite its train() method.
"""
model.train()
self.model = model
self.data_loader = data_loader
# to access the data loader iterator, call `self._data_loader_iter`
self._data_loader_iter_obj = None
self.optimizer = optimizer
self.gather_metric_period = gather_metric_period
self.zero_grad_before_forward = zero_grad_before_forward
self.async_write_metrics = async_write_metrics
# create a thread pool that can execute non critical logic in run_step asynchronically
# use only 1 worker so tasks will be executred in order of submitting.
self.concurrent_executor = concurrent.futures.ThreadPoolExecutor(max_workers=1)
def run_step(self):
"""
Implement the standard training logic described above.
"""
assert self.model.training, "[SimpleTrainer] model was changed to eval mode!"
start = time.perf_counter()
"""
If you want to do something with the data, you can wrap the dataloader.
"""
data = next(self._data_loader_iter)
data_time = time.perf_counter() - start
if self.zero_grad_before_forward:
"""
If you need to accumulate gradients or do something similar, you can
wrap the optimizer with your custom `zero_grad()` method.
"""
self.optimizer.zero_grad()
"""
If you want to do something with the losses, you can wrap the model.
"""
loss_dict = self.model(data)
if isinstance(loss_dict, torch.Tensor):
losses = loss_dict
loss_dict = {"total_loss": loss_dict}
else:
losses = sum(loss_dict.values())
if not self.zero_grad_before_forward:
"""
If you need to accumulate gradients or do something similar, you can
wrap the optimizer with your custom `zero_grad()` method.
"""
self.optimizer.zero_grad()
losses.backward()
self.after_backward()
if self.async_write_metrics:
# write metrics asynchronically
self.concurrent_executor.submit(
self._write_metrics, loss_dict, data_time, iter=self.iter
)
else:
self._write_metrics(loss_dict, data_time)
"""
If you need gradient clipping/scaling or other processing, you can
wrap the optimizer with your custom `step()` method. But it is
suboptimal as explained in https://arxiv.org/abs/2006.15704 Sec 3.2.4
"""
self.optimizer.step()
@property
def _data_loader_iter(self):
# only create the data loader iterator when it is used
if self._data_loader_iter_obj is None:
self._data_loader_iter_obj = iter(self.data_loader)
return self._data_loader_iter_obj
def reset_data_loader(self, data_loader_builder):
"""
Delete and replace the current data loader with a new one, which will be created
by calling `data_loader_builder` (without argument).
"""
del self.data_loader
data_loader = data_loader_builder()
self.data_loader = data_loader
self._data_loader_iter_obj = None
def _write_metrics(
self,
loss_dict: Mapping[str, torch.Tensor],
data_time: float,
prefix: str = "",
iter: Optional[int] = None,
) -> None:
logger = logging.getLogger(__name__)
iter = self.iter if iter is None else iter
if (iter + 1) % self.gather_metric_period == 0:
try:
SimpleTrainer.write_metrics(loss_dict, data_time, iter, prefix)
except Exception:
logger.exception("Exception in writing metrics: ")
raise
@staticmethod
def write_metrics(
loss_dict: Mapping[str, torch.Tensor],
data_time: float,
cur_iter: int,
prefix: str = "",
) -> None:
"""
Args:
loss_dict (dict): dict of scalar losses
data_time (float): time taken by the dataloader iteration
prefix (str): prefix for logging keys
"""
metrics_dict = {k: v.detach().cpu().item() for k, v in loss_dict.items()}
metrics_dict["data_time"] = data_time
storage = get_event_storage()
# Keep track of data time per rank
storage.put_scalar("rank_data_time", data_time, cur_iter=cur_iter)
# Gather metrics among all workers for logging
# This assumes we do DDP-style training, which is currently the only
# supported method in detectron2.
all_metrics_dict = comm.gather(metrics_dict)
if comm.is_main_process():
# data_time among workers can have high variance. The actual latency
# caused by data_time is the maximum among workers.
data_time = np.max([x.pop("data_time") for x in all_metrics_dict])
storage.put_scalar("data_time", data_time, cur_iter=cur_iter)
# average the rest metrics
metrics_dict = {
k: np.mean([x[k] for x in all_metrics_dict]) for k in all_metrics_dict[0].keys()
}
total_losses_reduced = sum(metrics_dict.values())
if not np.isfinite(total_losses_reduced):
raise FloatingPointError(
f"Loss became infinite or NaN at iteration={cur_iter}!\n"
f"loss_dict = {metrics_dict}"
)
storage.put_scalar(
"{}total_loss".format(prefix), total_losses_reduced, cur_iter=cur_iter
)
if len(metrics_dict) > 1:
storage.put_scalars(cur_iter=cur_iter, **metrics_dict)
def state_dict(self):
ret = super().state_dict()
ret["optimizer"] = self.optimizer.state_dict()
return ret
def load_state_dict(self, state_dict):
super().load_state_dict(state_dict)
self.optimizer.load_state_dict(state_dict["optimizer"])
def after_train(self):
super().after_train()
self.concurrent_executor.shutdown(wait=True)
class AMPTrainer(SimpleTrainer):
"""
Like :class:`SimpleTrainer`, but uses PyTorch's native automatic mixed precision
in the training loop.
"""
def __init__(
self,
model,
data_loader,
optimizer,
gather_metric_period=1,
zero_grad_before_forward=False,
grad_scaler=None,
precision: torch.dtype = torch.float16,
log_grad_scaler: bool = False,
async_write_metrics=False,
):
"""
Args:
model, data_loader, optimizer, gather_metric_period, zero_grad_before_forward,
async_write_metrics: same as in :class:`SimpleTrainer`.
grad_scaler: torch GradScaler to automatically scale gradients.
precision: torch.dtype as the target precision to cast to in computations
"""
unsupported = "AMPTrainer does not support single-process multi-device training!"
if isinstance(model, DistributedDataParallel):
assert not (model.device_ids and len(model.device_ids) > 1), unsupported
assert not isinstance(model, DataParallel), unsupported
super().__init__(
model, data_loader, optimizer, gather_metric_period, zero_grad_before_forward
)
if grad_scaler is None:
from torch.cuda.amp import GradScaler
grad_scaler = GradScaler()
self.grad_scaler = grad_scaler
self.precision = precision
self.log_grad_scaler = log_grad_scaler
def run_step(self):
"""
Implement the AMP training logic.
"""
assert self.model.training, "[AMPTrainer] model was changed to eval mode!"
assert torch.cuda.is_available(), "[AMPTrainer] CUDA is required for AMP training!"
from torch.cuda.amp import autocast
start = time.perf_counter()
data = next(self._data_loader_iter)
data_time = time.perf_counter() - start
if self.zero_grad_before_forward:
self.optimizer.zero_grad()
with autocast(dtype=self.precision):
loss_dict = self.model(data)
if isinstance(loss_dict, torch.Tensor):
losses = loss_dict
loss_dict = {"total_loss": loss_dict}
else:
losses = sum(loss_dict.values())
if not self.zero_grad_before_forward:
self.optimizer.zero_grad()
self.grad_scaler.scale(losses).backward()
if self.log_grad_scaler:
storage = get_event_storage()
storage.put_scalar("[metric]grad_scaler", self.grad_scaler.get_scale())
self.after_backward()
if self.async_write_metrics:
# write metrics asynchronically
self.concurrent_executor.submit(
self._write_metrics, loss_dict, data_time, iter=self.iter
)
else:
self._write_metrics(loss_dict, data_time)
self.grad_scaler.step(self.optimizer)
self.grad_scaler.update()
def state_dict(self):
ret = super().state_dict()
ret["grad_scaler"] = self.grad_scaler.state_dict()
return ret
def load_state_dict(self, state_dict):
super().load_state_dict(state_dict)
self.grad_scaler.load_state_dict(state_dict["grad_scaler"])